Module 3 : Actuators for robots Lecture 7 : Actuators for Robots-Part I Objectives In this course you will learn about Commercial or industrial manipulator's capabilities. Typical electrical drives in manipulators and their control Characteristics of such drives Introduction: Typical commercial / industrial manipulator capabilities. Articulated SCARA Reach 2.5 meter 1.2 meter Payload 125 Kg 10-50 Kg Waist rotation (degree) 360 120 Rotational speeds (degree) 100 to 200/sec Tip speed 2 meter/sec Repeatability 0.4 mm.03 to.05 mm Weight 1600 Kg 30-100 Kg Drives in Manipulators The term servo derived from phrase to serve, has meaning that the system that can be controlled. The electrical actuators that can be controlled are DC servomotors, AC servo motors and stepper motors. Following is an explanation of such motors. DC servo AC servo Stepper motor DC servo conventional motors A PMDC servo stator has permanent magnets and the rotor is wound. Brushes are used for commutation. Brushes wear and also cause noise. Brushless motors overcome these limitations. The electronic circuit
and rotor motion is sensed thru Hall's effect sensors. In robotic applications, the servo motor is required to produce rapid accelerations. In such system one needs to have motors with low inertia. Low inertia is achieved by reduced armature diameter with increase in armature length such that desired output power is achieved. Thus except minor differences in constructional features, DC servo motor is an ordinary DC motor. Motor Charecrerustucs PMDC motors have Characteristics as follows (Figure 7.2.2 and Figure 7.2.3) Figure 7.2.2 Figure 7.2.3 The power consumed by above motor has characteristics is shown in Figure 7.2.4 Figure 7.2.4
Contd... Application: 1. Continuous duty operation needs check for heat generation 2. Intermittent operation / motion /duty needs calculation of RMS torque as follows A typical Intermittent operation: (Refer Figure 7.2.5) 1. From O to A for t 1 Acceleration. Figure 7.2.5 2. From A to B for t 2 uniform velocity 3. From B to C for t 3 deceleration. 4. From C to D for t 4 Dwell, vel=0; Accn=0 The motor: PMDC motors rotate at high speeds and a gear-reducer is required to reduce the speed to requisite levels. In intermittent operations the angular velocity varies from instant to instant and choice of the gear reduction ratio G is critical. We are aware that torque drops as motor speed increases. As a first step we choose where = angular vel of load, = angular vel of motor and = angular accn. of load and = angular accn of motor We use the following rule for the preliminary selection of G 2 (Max speed of load) = G (Max allowable speed of motor ) l SIZING THE DRIVE for INTERMITTENT MOTION A few formulae Now we need to size the motor namely determine the torque and power. Let
I m --- Motor inertia I I ---- Load inertia ---- Joint Motor and gear box efficiency We know: One may compute the torque to be provided by motor to drive the load with Inertial I I as, I I = I I * * G= I I *G* *G=G 2 * I I * We thus have: Net torque = I m +G 2 I I Effective inertia= (I m + G 2 I I ) We shall now determine the RMS torque as follows for the motion which is as given in figure 7.4.1. This motion consists of accelerations, uniform velocities and decelerations. The first step is to compute the torque requirements for each of these portions of the cycle. This depends on the motor and gear-box inertias, the load inertial, efficiencies and so on. Table giving the torque computation for each portion of the cycle: (see Figure 7.4.2) O to A angular acceleration =
Torque T 1 = A to B ang accn= 0 constant vel. Torque T 2 = B to C t 3 ang accn= Torque T 3 = (Friction torque is subtracted here since friction aids deceleration) The RMS torque is thus given by: Selection of Motor The final selection of motor depends on the peak speed and peak torque requirements, where T Peak of (magnitudes) Max We use this data and the RMS value of torque to select the motor from the performance curves provided by the manufacturer. In addition to the above one has to check the heat generated by the motor as well as the natural frequency of the drive. Figure 7.5
Selecting Drive Electronics: Having selected the motor now we have to determine the basic parameters (current and voltage) required to select the dive electronics. We use the following formulae to determine the same: Current Voltage motor speed torque constant electrical constant R I V motor resistance current voltage Recap In this course you have learnt the following DC Servo motors drive DC servo motor selection for intermittent operation Congratulations, you have finished Lecture 7. To view the next lecture select it from the left hand side menu of the page.